Over the last decade, LED suppliers and chip designs have proliferated. “Not too long ago we were all limited to certain chip vendors for different products, and there wasn’t much differentiation between component manufacturers,” says Jason Baechler, president of lighting and lensing company MORITEX North America, Inc. (San Jose, California). “The sheer volume of options enables more applications because now you can get the required level of output or access certain wavelengths. End users don’t necessarily need to request something custom all the time for more challenging applications.”

Machine vision customers have more choices for coupling the LED to optics to better control the light’s output or directionality of the output, as well as having access to more light-controlling accessories. Baechler also cites a large variety of materials, some of which have trickled down from the flat-panel industry, now available to the machine vision market “so that we can produce lights with different directivity — not just based on the chip but what we couple it with, whether that’s an optical component or film,” he says.

Taking Some Heat
One of the biggest drawbacks of LEDs is the heat they generate. Because heat reduces LED efficiency, less light is produced. But improvements in thermal management of LEDs are addressing these challenges.

“LED manufacturers are creating better thermal bonding pads, and that creates better thermal contacts to help get the heat out. They’re also reducing the amount of wafer bonds inside the LED itself and using chip-scale packaging,” says Mark Kolvites, Technical Sales Manager at Metaphase Technologies (Bristol, Pennsylvania). “These features increase the lifetime and output of the LED.”

The improvements have prompted Metaphase to reevaluate its product line of LED lights to accommodate the increases in efficiency. “What we’re seeing now is that we can put out a whole lot more light compared to what we were doing a year ago just by driving the LED harder because the thermals are so much better,” Kolvites says.

Kolvites estimates that Metaphase’s lights are running about 15% to 20% cooler now using the same driver as a year ago. “We’re actually increasing our driver currents, taking more advantage of the light,” he says.

Because of the vast enhancements in efficiency, “there’s still a lot of potential intensity that we can unlock in those LEDs just by adding a bit more heat dissipation,” says Kevin High, Operations and Engineering Manager at Metaphase. “Customers are always asking for brighter lights so they can run shorter exposures and run their production lines even faster. In our standard products, we are not yet pushing anywhere near what they can do.”

Increases in overall optical efficiency have affected the design of MORITEX’s through-the-lens “coaxial” illumination for telecentric lenses. In these products, light goes through a beam splitter and then is projected through the lens optics.

“Even with the best designs this can create reflection, and efficiency has grown so much that we actually have to step down the illuminators so that we can control the light level to ensure there isn’t too much reflection that washes out an image or affects how the lens performs,” Baechler says.

Pick a Wavelength, Any Wavelength
Matt Pinter, head of engineering at Smart Vision Lights (Muskegon, Michigan), sees the biggest advancements in LED lighting coming not from the die or chip but rather from the availability of wavelengths for nearly any machine vision inspection task.

Research from the agriculture college at Michigan State University demonstrates the importance of wavelengths while offering lessons for the machine vision industry. Smart Vision Lights provided LED lights for a project that studied how wavelengths affect plant growth. Researchers found that certain wavelengths made plants grow while other ones made them bloom. The project also revealed that some types of lettuce only use one wavelength.

“You give the plants all these wavelengths and it’s a waste of time and energy,” Pinter says.

One wavelength garnering interest from machine vision customers is shortwave infrared (SWIR), primarily in response to increased demand for SWIR cameras. SWIR light penetrates a few millimeters of most materials. “With SWIR, you can solve applications that could have never been solved before by using visible or standard lower-wavelength IR,” says James Gardiner, Sales Engineer at Metaphase. “It’s not just a niche part of machine vision. It can be applied to any market, whether it’s health care, automotive, or technology.”

Gardiner offers the example of inspecting the seams and content of medical IV bags. “It’s very difficult to find a clear liquid in a clear material bag,” he says. “Especially in the 1450 nm IR spectrum, any water-based product will actually absorb the SWIR and appear black so that you can get very good contrast between a clear background and the water-based product.” The same goes for clear glues and lubricants commonly used in automotive applications.

Meanwhile, large tech companies are using SWIR lights for inspecting defects in silicon wafers, which become clear like glass beyond 1100 nm. “A good silicon wafer would appear invisible to the camera, so SWIR helps you create great contrast between it and the defect,” Gardiner says.

Smart Vision Lights also is fielding more requests for SWIR applications and has recently introduced its SWIR LED lights series. In addition to the 850–940 nm lights already offered by the company, new wavelengths include 1050 nm, 1200 nm, 1300 nm, 1450 nm, and 1550 nm.

Perhaps the biggest challenge with UV and IR lighting comes from the optics, as few options exist for diffusers that are effective on non-visible wavelengths. Without the proper optical diffusing material, the light can pass right through the object under test and create “hot spots,” which show up on the images where the light is too intense, therefore reducing the image’s overall contrast. Conversely, if the optical diffusing material absorbs too much light, none of it makes it to the object under test.

While the main type of material for LED optics is plastic, UV light will cause that to break down because of solarization. Materials such as fused quartz and fused silica offer high UV light transmission. Choices in optical materials for SWIR also are limited but include fused silica, germanium, calcium fluoride, and sapphire.

For several years, Smart Vision Lights has used silicone for the functions of housing, sealing, and lensing direction of its LED lights. According to Pinter, silicone optics have many advantages over their plastic and glass counterparts. Optical-grade silicone features a robust design that offers high transmission across a broad spectrum, withstands a large temperature range, and doesn’t react to UV light. Additionally, silicone molding is available at a fraction of the cost of plastic injection molding.

Doing More with Less
Machine vision designers are on a continual quest to create systems that are easier, cheaper, more flexible, and more compact. The machine vision lighting industry is responding with multispectral LED lights that support inspection at a single station with one camera and one light source.

“The more information you can get about a product, the better analysis you can do on it,” says Metaphase’s Gardiner. “When you can get that information not only in the visible spectrum but in the IR range as well, you have a more robust inspection.”

One of the first applications to use Metaphase’s RGB + IR LED Line Light was ground pork inspection. The customer used the RGB spectrum to ensure that the pork was the correct color. Meanwhile, the IR portion of the light accomplished something that visible light could not: It penetrated the surface of the meat to look for embedded contaminants such as a rubber glove.

While demand for multispectral lighting continues to rise, hyperspectral LEDs could represent the next frontier in machine vision lighting. Customers interested in hyperspectral LED lighting “want a true broadband, solid-state flat light from 600 nm to 1000 nm with every wavelength in there, rather than a multispectral light that has an 850 [nm] LED, a 940, and a 1300 with peaks and valleys in between,” says Smart Vision Lights’ Pinter.

Because hyperspectral LED lighting is in its infancy, customers still have to rely on broadband bulbs such as halogen, tungsten, and Xeon. “These bulbs throw away a lot of wavelength, so the LED would be custom tailored to a certain area of wavelength,” Pinter says.

The correct lighting is critical to another upward trend in machine vision: 3D imaging. For metrology applications, MORITEX integrates its LED light engine with the TI DLP® chipset from Texas Instruments. The DLP advanced light control product, which extends into the UV and IR spectra, uses programmable structured light patterns to produce 3D data in real time.

“The technology has been used in lithography for years, but we’re bringing it to the mainstream machine vision market for automated optic inspection applications, like measuring PCB components, microelectronics, and other high-end components,” Baechler says.

Although LED lighting development continues along a slow and steady path to greater efficiency, by combining the strength of more, and better controlled lighting, with improvements in optics, sensors, and software, machine vision capabilities continue to do the impossible: keeping pacing with the highest customer expectations. Can it last? If past performance is any guide, yes.

Thanks for sharing this. I would like to add few to your list.
1. Ecologically Friendly – LED Lighting Is Much More Eco-Friendly
LED lights are free of toxic chemicals. Most conventional fluorescent lighting bulbs contain a multitude of materials like e.g mercury that are dangerous for the environment.
LED lights contain no toxic materials and are 100% recyclable, and will help you to reduce your carbon footprint by up to a third. The long operational life time span mentioned above means also that one LED light bulb can save material and production of 25 incandescent light bulbs. A big step towards a greener future!
2. Durable Quality – LED Illumination Can Withstand Rough Conditions
LEDs are extremely durable and built with sturdy components that are highly rugged and can withstand even the roughest conditions.
Because LED lights are resistant to shock, vibrations and external impacts, they make great outdoor lighting systems for rough conditions and exposure to weather, wind, rain or even external vandalism, traffic related public exposure and construction or manufacturing sites.
3. Zero UV Emissions – LED Lighting Features Close to No UV Emissions
LED illumination produces little infrared light and close to no UV emissions.
Because of this, LED lighting is highly suitable not only for goods and materials that are sensitive to heat due to the benefit of little radiated heat emission, but also for illumination of UV sensitive objects or materials such a in museums, art galleries, archeological sites etc.
4. Operational in Extremely Cold or Hot Temperatures
LED are ideal for operation under cold and low outdoor temperature settings. For fluorescent lamps, low temperatures may affect operation and present a challenge, but LED illumination operates well also in cold settings, such as for outdoor winter settings, freezer rooms etc.
5. Low-Voltage – LED Lighting Can Run on Low-Voltage Power Supply
A low-voltage power supply is sufficient for LED illumination. This makes it easy to use LED lighting also in outdoor settings, by connecting an external solar-energy source and is a big advantage when it comes to using LED technology in remote or rural areas.

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